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Relationship between energy expenditure, nutritional status and clinical severity before starting enteral nutrition in critically ill children

Published online by Cambridge University Press:  28 January 2011

Marta Botrán
Affiliation:
Paediatric Intensive Care Department, Hospital General Universitario Gregorio Marañón, Dr Castelo 47, 28009Madrid, Spain
Jesús López-Herce*
Affiliation:
Paediatric Intensive Care Department, Hospital General Universitario Gregorio Marañón, Dr Castelo 47, 28009Madrid, Spain
Santiago Mencía
Affiliation:
Paediatric Intensive Care Department, Hospital General Universitario Gregorio Marañón, Dr Castelo 47, 28009Madrid, Spain
Javier Urbano
Affiliation:
Paediatric Intensive Care Department, Hospital General Universitario Gregorio Marañón, Dr Castelo 47, 28009Madrid, Spain
Maria José Solana
Affiliation:
Paediatric Intensive Care Department, Hospital General Universitario Gregorio Marañón, Dr Castelo 47, 28009Madrid, Spain
Ana García
Affiliation:
Paediatric Intensive Care Department, Hospital General Universitario Gregorio Marañón, Dr Castelo 47, 28009Madrid, Spain
Angel Carrillo
Affiliation:
Paediatric Intensive Care Department, Hospital General Universitario Gregorio Marañón, Dr Castelo 47, 28009Madrid, Spain
*
*Corresponding author: Dr J. López-Herce, fax +34 915 868 018, email pielvi@hotmail.com
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Abstract

The objective of the present study was to investigate the relationship between energy expenditure (EE), biochemical and anthropometric nutritional status and severity scales in critically ill children. We performed a prospective observational study in forty-six critically ill children. The following variables were recorded before starting nutrition: age, sex, diagnosis, weight, height, risk of mortality according to the Paediatric Risk Score of Mortality (PRISM), the Revised Paediatric Index of Mortality (PIM2) and the Paediatric Logistic Organ Dysfunction (PELOD) scales, laboratory parameters (albumin, total proteins, prealbumin, transferrin, retinol-binding protein, cholesterol and TAG, and nitrogen balance) and EE measured by indirect calorimetry. The results showed that there was no relationship between EE and clinical severity evaluated using the PRISM, PIM2 and PELOD scales or with the anthropometric nutritional status or biochemical alterations. Finally, it was concluded that neither nutritional status nor clinical severity is related to EE. Therefore, EE must be measured individually in each critically ill child using indirect calorimetry.

Type
Full Papers
Copyright
Copyright © The Authors 2011

Nutrition is one of the cornerstones of management of critically ill paediatric patients. Between 40 and 70 % of critically ill children present some degree of malnutrition, and this impairs the response to disease and increases the susceptibility to infection and to the onset of multi-organ failure, leading to a substantial rise in morbidity and mortality(Reference López-Herce Cid, Sánchez Sánchez and Mencía Bartolomé1Reference Havalad, Quaid and Sapiega5).

The most appropriate form of energy delivery and the nutrient composition for these patients still remains to be established(Reference López-Herce Cid, Sánchez Sánchez and Mencía Bartolomé1, Reference Skillman and Wischmeyer2, Reference Havalad, Quaid and Sapiega5). Although some critically ill children present a hypermetabolic state (major burns, multiple injuries and prolonged admission), the majority have a lower energy expenditure (EE) than healthy children, particularly those on mechanical ventilation or with sedation and muscle relaxation(Reference Shakur, Richards and Pencharz6Reference Stewart, Godoy and Branson12).

Insufficient energy delivery leads to depletion of fat and protein reserves, reducing the ability of the body to react to aggression and impairing the immune response, increasing the susceptibility to infection(Reference López-Herce Cid, Sánchez Sánchez and Mencía Bartolomé1Reference Havalad, Quaid and Sapiega5). An excessive energy delivery over a long period, on the other hand, can cause hepatic steatosis and an increase in CO2 production, prolonging the time on mechanical ventilation. There is enormous variability in the nutritional requirements of critically ill children(Reference Shakur, Richards and Pencharz6Reference Joosten, Verhoeven and Hazelzet8, Reference Briassoulis, Michaeloudi and Fitrolaki13Reference McLellan, Wals and Burdess16); it is therefore important to adjust energy delivery individually to the EE of each patient(Reference Coss-Bu, Klish and Walding7, Reference Joosten, Verhoeven and Hazelzet8, Reference Van der Kuip, de Meer and Westerterp15Reference Mehta and Compher17).

Although there are numerous formulas for calculating the energy delivery that critically ill children require, none of them has been shown to have good concordance with true EE(Reference Shakur, Richards and Pencharz6Reference Joosten, Verhoeven and Hazelzet8, Reference Stewart, Godoy and Branson12Reference Fulbrook, Bongers and Albarran18). Indirect calorimetry is the best method for measuring EE in critically ill children, but its use has still not become widespread, and even today many paediatric intensive care units (PICU) continue only to use the formulas(Reference Campos Miño and Sasbón19, Reference Hulst, van Goudoever and Zimmermann20).

The objective of the present study was to determine whether there is any relationship between EE and biochemical and anthropometric nutritional status and clinical severity on admission to the intensive care unit. The hypothesis of the present study was that children with lower anthropometric and biochemical protein parameters of nutrition have lower EE. The presence of a relationship would enable energy delivery to be adapted to the theoretical expenditure in these patients.

Patients and methods

A prospective observational study was performed. The present study was conducted according to the guidelines laid down in the Declaration of Helsinki, and all procedures involving patients were approved by the local Institutional Review Board. Written informed consent was obtained from the parents of the participating children. The study population comprised of patients aged between 1 month and 16 years admitted to the PICU, on mechanical ventilation, with a fraction of inspired oxygen ≤ 60 %, and who were nil-by-mouth before starting enteral nutrition, only receiving intravenous glucose infusions. Patients on high-frequency mechanical ventilation or extracorporeal membrane oxygenation were excluded due to the technical difficulty of measuring EE.

Epidemiological and anthropometric variables (age, sex, diagnosis on admission, weight and height) were recorded. The risk of mortality was calculated using the Paediatric Risk Score of Mortality (PRISM)(Reference Pollack, Ruttimann and Getson21), the Revised Paediatric Index of Mortality(Reference Slater, Shann and Pearson22) and the Paediatric Logistic Organ Dysfunction(Reference Leteurtre, Martinot and Duhamel23) scales. The following laboratory parameters of nutrition were measured in serum: prealbumin, transferrin, retinol-binding protein by nephelometry using the BN2 Siemens (Medical Solutions Diagnostics GmbH, Bad Nauheim, Germany), and albumin (turbidimetry), total proteins (turbidimetry–Biuret), urea (enzymatic-UV ureasa), cholesterol and TAG (enzymatic-UV turbidimetry) using the Cobas Integra 400 plus (Roche Diagnostica, Hoffman-La Roche, Basel, Switzerland). Urinary urea was determined (enzymatic-UV ureasa turbidimetry) using the Cobas Integra 400 plus (Roche Diagnostica), and nitrogen balance was calculated.

Before starting the nutrition, baseline calorimetry was performed in all patients using the Datex S5 monitor (E-COVX; GE Healthcare/Datex-Ohmeda, Helsinki, Finland). The duration of the measurement was between 1 and 2 h and, during that time, the respiratory support parameters were not altered. The following data were recorded: VO2, CO2 production, EE and the respiratory quotient.

Based on weight on admission, patients were classified into underweight (weight lower than tenth percentile for age and sex) and normal-weight (weight above tenth percentile) groups according to the local standard references(Reference Carrascosa Lezcano, Fernández García and Fernández Ramos24). The children also were grouped according to a risk of mortality higher or lower than 5 %, based on the PRISM, the Paediatric Logistic Organ Dysfunction and the Revised Paediatric Index of Mortality scores.

Statistical analysis was performed using the SPSS version 16.0 statistical package (SPSS, Inc., Chicago, IL, USA). The Kolmogorov–Smirnov test was used to determine normality of the data. The χ2 test, Fisher's exact test, Mann–Whitney and Kruskal–Wallis tests were used to compare the qualitative and quantitative variables. Correlations were determined using the Pearson and Spearman tests. Significance was taken as a P value < 0·05.

Results

The study population comprised of forty-six patients aged between 1 month and 16 years. Of these, 63 % were less than 1-year-old and 56·5 % were male. The reason for admission to the PICU was for postsurgical care in thirty-six patients (78·2 %; thirty in the postoperative period of cardiac surgery and six after surgery to the airway) and for medical conditions in ten patients (21·8 %; three with heart failure, four with respiratory failure, one with sepsis, one with meningoencephalitis and one with multiple injuries). The median duration of PICU admission and mechanical ventilation before the beginning of the study was 18 and 20 h, respectively (range 12–48 h) for both measures. None of the patients died during the study.

Table 1 shows the clinical and anthropometric characteristics and the biochemical nutritional parameters. Body weight was below the tenth percentile in 71·7 % of the patients and below the third percentile in 58·7 % of the patients. The percentage of patients who presented alterations in the biochemical nutritional parameters according to our paediatric local reference values was as follows: total proteins < 45 g/l, 15·6 %; albumin < 30 g/l, 26·7 %; prealbumin < 100 mg/l, 35·3 %; retinol-binding protein < 30 mg/l, 96·7 %; transferrin < 2000 mg/l, 80·6 %; TAG < 500 mg/l, 50 %; cholesterol < 1000 mg/l, 82·1 %.

Table 1 Clinical characteristics and biochemical and anthropometric nutritional parameters of the patients

(Median values and 25th (P25) and 75th (P75) percentiles)

PRISM, Paediatric Risk Score of Mortality; PIM2, Revised Paediatric Index of Mortality; PELOD, Paediatric Logistic Organ Dysfunction; RQ, respiratory quotient.

The median EE was 204·2 kJ/kg per d (48·8 kcal/kg per d), and the median respiratory quotient was 0·74. EE lower than 167·4 kJ/kg per d (40 kcal/kg per d) was detected in 32·6 % of the children, and EE was over 251 kJ/kg (60 kcal/kg) in only 23·9 % of the children. EE per kg correlated with body weight (r 0·485, P = 0·001) but not with body weight related to age. There was an inverse correlation between body weight and nitrogen balance (r − 0·70, P = 0·001). Weight and EE were not found to be correlated with any of the other biochemical parameters.

None of the patients presented a positive nitrogen balance at the time of starting nutrition. Intravenous albumin had been administered to 26·7 % of the patients in 24 h before the study. There were no significant differences in the serum albumin and total protein levels between the patients who received albumin (32 (sd 6) and 52 (sd 7) g/l, respectively) and those who did not (33 (sd 5) and 55 (sd 8) g/l, respectively), nor were there any differences in nitrogen balance between the two groups.

Table 2 shows a comparison between the underweight patients (P < 10) and those with a normal weight. The comparison between the patients with weights below the third percentile and above the third percentile was similar (data not shown). No differences were detected between the two groups in the clinical state, in the severity scores, in EE or in the majority of biochemical measurements. The percentages of patients with EE below 167·4 kJ/kg per d (40 kcal/kg per d) or above 251 kJ/kg per d (60 kcal/kg per d) were similar in the two groups. However, patients with a normal weight had a significantly more negative nitrogen balance than those with underweight.

Table 2 Comparison between the patients with underweight (weight≤tenth percentile (P10)) and the patients with a normal weight (weight>P10)

(Median values and 25th (P25) and 75th (P75) percentiles)

PRISM, Paediatric Risk Score of Mortality; PIM2, Revised Paediatric Index of Mortality; PELOD, Paediatric Logistic Organ Dysfunction; RQ, respiratory quotient.

When comparing patients according to their EE (Table 3), it was found that children with EE below 167·4 kJ/kg per d (40 kcal/kg per d) were younger and had a lower body weight and height than children with higher EE; they also had a significantly lower respiratory quotient and a less negative nitrogen balance. There were no significant differences in the proportion of underweight children between the patients with EE below 167·4 kJ/kg per d (40 kcal/kg per d) (60 %) and those with EE more than 167·4 kJ/kg per d (40 kcal/kg per d) (58·1 %) (P = 1). No other differences were found in the values of the biochemical parameters.

Table 3 Comparison between the patients with energy expenditure (EE) lower and higher than 167·4 kJ/kg (40 kcal/kg) and EE lower and higher than 251 kJ/kg (60 kcal/kg)

(Median values and 25th (P25) and 75th (P75) percentiles)

PRISM, Paediatric Risk Score of Mortality; PIM2, Revised Paediatric Index of Mortality; PELOD, Paediatric Logistic Organ Dysfunction; RQ, respiratory quotient.

Children with an EE>251 kJ/kg per d (60 kcal/kg per d) had a significantly higher age and weight than the other patients (Table 3). No differences were found in the values of the biochemical parameters, except for higher total protein and transferrin levels in the patients with higher EE.

There were no significant differences in EE or in the biochemical parameters on comparing the patients with a risk of mortality above or below 5 % according to the PRISM, the Revised Paediatric Index of Mortality and the Paediatric Logistic Organ Dysfunction scales (data not shown).

Table 4 shows a comparison between the patients admitted for postsurgical care and those with medical conditions. There were no differences in EE between the two groups. The percentage of postsurgical patients with weights below the third percentile (66·7 %) was significantly higher than among patients with medical conditions (30 %) (P = 0·037). However, children with medical conditions presented significantly lower levels of albumin, prealbumin and retinol-binding protein than the postsurgical patients. There were no differences between the two groups in the other biochemical parameters studied.

Table 4 Comparison between the patients admitted for postsurgical care and those admitted for medical conditions

(Median values and 25th (P25) and 75th (P75) percentiles)

PRISM, Paediatric Risk Score of Mortality; PIM2, Revised Paediatric Index of Mortality; PELOD, Paediatric Logistic Organ Dysfunction; RQ, respiratory quotient.

A comparison between the children with heart disease and those with other conditions is presented in Table 5. There were no differences between the two groups with regard to EE, anthropometric status or the majority of biochemical parameters.

Table 5 Comparison between the children with heart disease and other patients

(Median values and 25th (P25) and 75th (P75) percentiles)

PRISM, Paediatric Risk Score of Mortality; PIM2, Revised Paediatric Index of Mortality; PELOD, Paediatric Logistic Organ Dysfunction; RQ, respiratory quotient.

Discussion

The present study shows that a large percentage of children who are admitted to intensive care units present underweight and lower levels of protein biochemical parameters. Our data coincide with the findings in other series in children(Reference López-Herce Cid, Sánchez Sánchez and Mencía Bartolomé1Reference Havalad, Quaid and Sapiega5). In the present study, there were no significant differences in the majority of biochemical parameters between patients with underweight and those with a normal weight. Other authors have also found no significant association between abnormalities in the biochemical parameters and the anthropometric measurements in critically ill children(Reference Taylor, Cheeseman and Preedy25).

Critically ill children suffer intense metabolic stress, and, in addition, they are in a growth and development phase. Inadequate nutritional support can have a negative impact on their vital prognosis and on recovery from disease.

Various studies in critically ill children have shown that the concordance between EE measured by indirect calorimetry and the value estimated by formulas is not good(Reference Shakur, Richards and Pencharz6Reference Joosten, Verhoeven and Hazelzet8, Reference Stewart, Godoy and Branson12Reference Fulbrook, Bongers and Albarran18), leading to a high incidence of underfeeding or overfeeding(Reference Shakur, Richards and Pencharz6, Reference McLellan, Wals and Burdess16, Reference Mehta and Compher17). This is because the majority of these formulas are based almost exclusively on weight and height, and in some cases they have not been designed for or validated in children, and, in particular, they do not take into account other factors that could affect EE, such as the type and severity of the disease(Reference Shakur, Richards and Pencharz6, Reference Stroud9, Reference Hoffer10, Reference McLellan, Wals and Burdess16, Reference Campos Miño and Sasbón19).

The present study is the first to have analysed whether there is a relationship between EE and the state of clinical severity measured using three mortality risk indices and anthropometric or biochemical nutritional status in critically ill children. The mean EE in our patients was similar to that found in other series of critically ill children, with a very broad range, indicating the presence of a wide inter-individual variability(Reference Shakur, Richards and Pencharz6Reference Joosten, Verhoeven and Hazelzet8, Reference Stewart, Godoy and Branson12Reference Fulbrook, Bongers and Albarran18).

In the present study, we found no relationship between EE at the time of starting nutrition and the anthropometric and biochemical evaluation of the nutritional status, or with clinical severity measured using the PRISM, the Revised Paediatric Index of Mortality and the Paediatric Logistic Organ Dysfunction scales. The most seriously ill children did not have higher EE or higher percentage of underweight or biochemical protein alterations. Other authors have also been unable to find any relationship between the PRISM score and EE(Reference Joosten, Verhoeven and Hazelzet8).

Some studies have reported that patients with sepsis have higher EE than surgical patients(Reference Coss-Bu, Klish and Walding7). In the present study, we found no relationship between EE and the type of patient, medical or surgical. Children with underweight did not have higher EE than those with a normal weight.

Indirect calorimetry is the best tool for controlling nutrition in critically ill paediatric patients, as it enables EE to be calculated simply and quickly in each patient. The majority of studies of indirect calorimetry have used a specific instrument (Deltatract® Datex-Ohmeda, Helsinki, Finland) that requires a considerable economic outlay(Reference Coss-Bu, Klish and Walding7Reference Stroud9, Reference Stewart, Godoy and Branson12, Reference Mehta and Compher17, Reference Fulbrook, Bongers and Albarran18). In the present study, we used a new measuring device that is simpler and cheaper and that connects to a multi-parameter monitor. This device shows a good correlation with the Deltatract(Reference Shakur, Richards and Pencharz6, Reference Vazquez Martinez, Dorao Martínez-Romillo and Diez Sebastian26Reference Hulst, van Goudoever and Zimmermann29); its drawback is that calorimetry can only be performed in patients on mechanical ventilation(Reference Shakur, Richards and Pencharz6, Reference Mehta, Bechard and Leavitt27).

The present study has certain limitations. The sample size was relatively small, and a large percentage of the patients were surgical, reducing the power of the statistical comparisons between the different diagnostic groups. The study population has a broad, but skewed, age range. About 75 % of the children were 2 years of age or younger. This fact could make more difficult the analysis and interpretation of the data. However, this is the representation of the real population of our PICU, and we think of most of the PICU in the world. Furthermore, the objective of the study was to assess the relationship between the initial state of the patients and their energy requirements at the time of starting nutrition, and we therefore did not study the changes in EE in these patients. However, some studies have found that there are no significant variations in EE over the course of a patient's admission to intensive care(Reference Coss-Bu, Klish and Walding7).

We only used weight as the anthropometric measure of nutrition status because, in critically ill patients, acute malnutrition is the more frequent and important kind of malnutrition. Moreover, in these patients, it is not always possible to measure the height.

We conclude that, in critically ill children, there is no correlation between EE and anthropometric and biochemical nutritional status or clinical severity. Thus, neither the nutritional status, evaluated using anthropometric (weight) or protein biochemical measurements, nor the clinical severity on admission will help to determine the energy delivery that a critically ill child requires. It is therefore necessary to measure EE individually using indirect calorimetry in each critically ill child.

Acknowledgements

The authors declare no conflict of interests and no funding. The present study has been supported in part by a grant from the Carlos III Health Institute of Spain (grant no. RD08/0072: Maternal, Child Health and Development Network) within the framework of the VI National I+D+i Research Program (2008-1). The authors are grateful to the nurses and doctors of the PICU of Gregorio Marañón University General Hospital, Madrid, Spain, for their collaboration in conducting the present study. M. B. participated in the design of the study, carried out the studies and data analyses and drafted the manuscript. J. L.-H. conceived the study, participated in its design, coordination and supervision, carried out the data analyses and drafted the manuscript. S. M. participated in the design of the study and carried out the data analyses and the statistical analysis. J. U., M. J. S. and A. G. carried out the studies and data analyses. A. C. participated in the design of the study and drafted the manuscript. All authors read and approved the final manuscript.

References

1López-Herce Cid, J, Sánchez Sánchez, C, Mencía Bartolomé, S, et al. (2007) Energy expenditure in critically ill children: correlation with clinical characteristics, caloric intake, and predictive equations. An Pediatr (Barc) 66, 229239.CrossRefGoogle ScholarPubMed
2Skillman, HE & Wischmeyer, PE (2008) Nutrition therapy in critically ill infants and children. JPEN 32, 520534.CrossRefGoogle ScholarPubMed
3López-Herce Cid, J (2009) Nutrition in the critically ill child. An Pediatr (Barc) 71, 14.Google Scholar
4Oosterveld, MJ, Van Der Kuip, M, De Meer, K, et al. (2006) Energy expenditure and balance following pediatric intensive care unit admission: a longitudinal study of critically ill children. Pediatr Crit Care Med 7, 147153.Google Scholar
5Havalad, S, Quaid, MA & Sapiega, V (2006) Energy expenditure in children with severe head injury: lack of agreement between measured and estimated energy expenditure. Nutr Clin Pract 21, 175181.Google Scholar
6Shakur, YA, Richards, H & Pencharz, PB (2008) Is it necessary to measure resting energy expenditure in clinical practice in children? J Pediatr 152, 437439.CrossRefGoogle ScholarPubMed
7Coss-Bu, JA, Klish, WJ, Walding, D, et al. (2001) Energy metabolism nitrogen balance and substrate utilization in critically ill children. Am J Clin Nutr 74, 664669.CrossRefGoogle ScholarPubMed
8Joosten, K, Verhoeven, JJ & Hazelzet, JA (1999) Energy expenditure and substrate utilization in mechanically ventilated children. Nutrition 15, 444448.Google Scholar
9Stroud, M (2007) Protein and the critically ill; do we know what to give? Proc Nutr Soc 66, 378383.Google Scholar
10Hoffer, LJ (2003) Protein and energy provision in critical illness. Am J Clin Nutr 78, 906911.Google Scholar
11Sancho Martínez, A, Dorao Martínez-Romillo, P & Ruza Tarrío, F (2008) Valoración del gasto energético en los niños. Implicaciones fisiológicas y clínicas. Métodos de medición (Assessment of energy expenditure in children. Physiological and clinical implications). An Pediatr (Barc) 68, 165180.Google Scholar
12Stewart, CL, Godoy, CM & Branson, R (2005) Comparison of two systems of measuring energy expenditure. JPEN 29, 212217.Google Scholar
13Briassoulis, G, Michaeloudi, E, Fitrolaki, DM, et al. (2009) Influence of different ventilator modes on VO2 and VCO2 measurements using a compact metabolic monitor. Nutrition 25, 11061114.Google Scholar
14Singer, P, Pogrebetsky, I, Attal-Singer, J, et al. (2006) Comparison of metabolic monitors in critically ill, ventilated patients. Nutrition 22, 10771086.CrossRefGoogle ScholarPubMed
15Van der Kuip, M, de Meer, K, Westerterp, KR, et al. (2007) Physical activity as a determinant of total energy expenditure in critically ill children. Clin Nutr 26, 744751.Google Scholar
16McLellan, S, Wals, T, Burdess, A, et al. (2002) Comparison between the Datex-Ohmeda M-COVX metabolic monitor and the Deltatrac II in mechanically ventilated patients. Intensive Care Med 28, 870876.CrossRefGoogle Scholar
17Mehta, NM, Compher, CH & A.S.P.E.N. Board of Directors (2009) A.S.P.E.N. clinical guidelines: nutrition support of the critically ill child. JPEN 33, 260276.Google Scholar
18Fulbrook, P, Bongers, A & Albarran, JW (2007) A European survey of enteral nutrition practices and procedures in adult intensive care units. J Clin Nurs 16, 21322141.CrossRefGoogle ScholarPubMed
19Campos Miño, S & Sasbón, JS (2009) The Latin-American survey on nutrition in Pediatric Intensive Care (ELAN-CIP). An Pediatr (Barc) 71, 512.Google Scholar
20Hulst, JM, van Goudoever, JB, Zimmermann, LJ, et al. (2006) The role of initial monitoring of routine biochemical nutritional markers in critically ill children. J Nutr Biochem 17, 5762.Google Scholar
21Pollack, MM, Ruttimann, UE & Getson, PR (1988) The pediatric risk of mortality (PRISM) score. Crit Care Med 16, 11101116.Google Scholar
22Slater, A, Shann, F & Pearson, G (2003) PIM 2: a revised version of the Paediatric Index of Mortality. Intensive Care Med 29, 278285.Google Scholar
23Leteurtre, S, Martinot, A, Duhamel, A, et al. (2003) Validation of pediatric logistic organ dysfunction (PELOD) score. Prospective, observational, multicenter study. Lancet 362, 192197.CrossRefGoogle Scholar
24Carrascosa Lezcano, A, Fernández García, JM, Fernández Ramos, C, et al. (2008) Spanish cross-sectional growth study 2008. Part II. Height, weight and body mass index values from birth to adulthood. An Pediatr (Barc) 68, 552569.Google Scholar
25Taylor, RM, Cheeseman, P, Preedy, V, et al. (2003) Can energy expenditure be predicted in critically ill children? Pediatr Crit Care Med 4, 176180.CrossRefGoogle ScholarPubMed
26Vazquez Martinez, JL, Dorao Martínez-Romillo, P, Diez Sebastian, J, et al. (2004) Predicted versus measured energy expenditure by continuous, online indirect calorimetry in ventilated, critically ill children during the early postinjury period. Pediatr Crit Care Med 5, 1927.Google Scholar
27Mehta, NM, Bechard, LJ, Leavitt, K, et al. (2009) Cumulative energy imbalance in the pediatric intensive care unit: role of targeted indirect calorimetry. JPEN 33, 336344.Google Scholar
28Mehta, NM & Duggan, CP (2009) Nutritional deficiencies during critical illness. Pediatr Clin North Am 56, 11431160.CrossRefGoogle ScholarPubMed
29Hulst, JM, van Goudoever, JB, Zimmermann, LJ, et al. (2004) The effect of cumulative energy and protein deficiency on anthropometric parameters in a pediatric ICU population. Clin Nutr 23, 13811389.Google Scholar
Figure 0

Table 1 Clinical characteristics and biochemical and anthropometric nutritional parameters of the patients(Median values and 25th (P25) and 75th (P75) percentiles)

Figure 1

Table 2 Comparison between the patients with underweight (weight≤tenth percentile (P10)) and the patients with a normal weight (weight>P10)(Median values and 25th (P25) and 75th (P75) percentiles)

Figure 2

Table 3 Comparison between the patients with energy expenditure (EE) lower and higher than 167·4 kJ/kg (40 kcal/kg) and EE lower and higher than 251 kJ/kg (60 kcal/kg)(Median values and 25th (P25) and 75th (P75) percentiles)

Figure 3

Table 4 Comparison between the patients admitted for postsurgical care and those admitted for medical conditions(Median values and 25th (P25) and 75th (P75) percentiles)

Figure 4

Table 5 Comparison between the children with heart disease and other patients(Median values and 25th (P25) and 75th (P75) percentiles)